WO2023017924A1 - System and method for reliquefaction of boil-off gas of ship and system and method for treating offgas of reliquefaction apparatus - Google Patents

Abstract

Disclosed are a system and method for reliquefaction of a boil-off gas of a ship and a system and method for treating an offgas of a reliquefaction apparatus. The system for reliquefaction of a boil-off gas of a ship, of the present invention, comprises: a compressor which compresses the boil-off gas generated from the liquefied gas stored in a storage tank provided on a ship; a heat exchanger in which the compressed gas compressed in the compressor is cooled; a refrigerant circulation line through which the refrigerant supplied to the heat exchanger circulates; a warming line which is connected from the storage tank to the compressor; and a heater which is provided in the warming line, wherein, in the heater, the boil-off gas is heated to an appropriate input temperature of the compressor.

Description

Ship's boil-off gas re-liquefaction system and method, off-gas treatment system and method of re-liquefaction device

The present invention provides a re-liquefaction system and method for re-liquefying boil-off gas (BOG) generated from liquefied gas stored in a storage tank of a ship and recovering it to a storage tank, and a nitrogen content separated from a separator of a re-liquefaction device. It relates to an off-gas treatment system and method of a re-liquefaction device capable of maintaining the re-liquid performance of the re-liquefaction device by discharging and treating the high off-gas.

Natural gas (natural gas) has methane (methane) as a main component, and there is little emission of environmental pollutants during combustion, so it is attracting attention as an eco-friendly fuel. Liquefied Natural Gas (LNG) is obtained by liquefying natural gas by cooling it to about -163°C under atmospheric pressure, and since its volume is reduced to about 1/600 of that in gaseous state, it is suitable for long-distance transportation through sea. very suitable Therefore, natural gas is mainly stored and transported in the form of liquefied natural gas, which is easy to store and transport.

Since the liquefaction point of natural gas is a cryogenic temperature of about -163 ° C. at atmospheric pressure, it is common for LNG storage tanks to be insulated so that LNG can remain in a liquid state. However, although the LNG storage tank is insulated, there is a limit to blocking external heat, and since external heat is continuously transferred to the LNG storage tank, LNG is continuously stored in the LNG storage tank during the LNG transportation process. It is vaporized and boil-off gas (BOG) is generated.

When boil-off gas is continuously generated in the LNG storage tank, it becomes a factor that increases the internal pressure of the LNG storage tank. If the internal pressure of the storage tank exceeds the set safety pressure, it may cause an emergency situation such as tank rupture, so the boil-off gas must be discharged to the outside of the storage tank using a safety valve. However, boil-off gas is a kind of LNG loss, and since it is an important problem in the transportation efficiency and fuel efficiency of LNG, various methods for treating boil-off gas generated in the storage tank are used.

Recently, a method of using boil-off gas at a fuel demand place such as a ship's engine, a method of re-liquefying boil-off gas and recovering it to a storage tank, or a method of using these two methods in combination have been developed and applied.

The present applicant uses the boil-off gas itself as a refrigerant without a separate refrigerant to re-liquefy the boil-off gas. After cooling the boil-off gas compressed by the compressor by exchanging heat with the boil-off gas before being compressed by the compressor, A method of re-liquefying a part of the boil-off gas by expanding it has been invented, and such a system is called a PRS (Partial Re-liquefaction System).

When the amount of boil-off gas is large due to the large amount of liquefied gas inside the storage tank, when the amount of boil-off gas to be re-liquefied is large, such as when the ship is anchored or operated at low speed and the boil-off gas used in the engine is small , PRS alone may not satisfy the required amount of re-liquefaction, so the present applicant invented a technique for improving PRS to re-liquefy more boil-off gas.

As an improved technology of PRS, a system that enables additional cooling of boil-off gas by a refrigerant cycle using boil-off gas itself as a refrigerant is called Methane Refrigeration System (MRS).

A mixed refrigerant or a separate refrigerant such as nitrogen may be used to cool the boil-off gas to be re-liquefied.

In the case of applying a re-liquefaction cycle to re-liquefy boil-off gas in a ship, typical liquefaction methods that can be adopted include processes using an SMR cycle and a C3MR cycle. The C3MR cycle (Propane-precooled Mixed Refrigerant Cycle) is a process of cooling natural gas using a single propane refrigerant, and then liquefying and supercooling it using a mixed refrigerant. It is a process of liquefying natural gas using a mixed refrigerant composed of refrigerants.

Both the SMR cycle and the C3MR cycle are processes using mixed refrigerants. When the refrigerant leaks during the liquefaction process and the composition ratio of the mixed refrigerant changes, the liquefaction efficiency decreases. The composition of the refrigerant must be maintained by filling the components.

As another method of the re-liquefaction cycle for re-liquefying boil-off gas, a single cycle liquefaction process using a nitrogen refrigerant may be used.

Nitrogen refrigerant has a relatively low efficiency compared to a cycle using a mixed refrigerant, but has a high safety because the refrigerant is inert and is easier to apply to ships because there is no phase change of the refrigerant.

On the other hand, in a ship equipped with an engine capable of using boil-off gas as fuel, a compressor for supplying fuel to the engine can be used to re-liquefy the boil-off gas. These compressors are provided in accordance with the fuel supply conditions required by the engine, but also require the temperature of boil-off gas introduced into the compressor to be in an appropriate range to prevent damage to the device.

In addition, when the conventional re-liquefaction device is operated, the re-liquefied boil-off gas is recovered to the storage tank after gas-liquid separation, and the separated gas is recycled to the re-liquefaction device together with the boil-off gas generated in the storage tank.

However, boil-off gas generated from the storage tank contains components other than methane. Nitrogen, which has a lower liquefaction point than methane, is not liquefied even if it passes through the re-liquefaction device. increases gradually, which leads to deterioration of the performance of the liquid.

The present invention is intended to solve this problem, and proposes a system capable of improving re-liquefaction performance by effectively cooling boil-off gas to be re-liquefied while controlling the boil-off gas temperature within an appropriate range required by a compressor.

In addition, the present invention is to propose a method capable of maintaining the re-liquefaction performance of the re-liquefaction device by discharging and treating the off-gas having a high nitrogen content separated by gas-liquid separation through the re-liquefaction device.

According to one aspect of the present invention for solving the above problems, a compressor for compressing boil-off gas generated from liquefied gas stored in a storage tank provided in a ship;

a heat exchanger cooling the compressed gas compressed by the compressor;

a refrigerant circulation line through which the refrigerant supplied to the heat exchanger circulates;

Ga line connected from the storage tank to the compressor; and

Including: a heater provided in the ga-line,

The heater provides a boil-off gas re-liquefaction system of a ship, characterized in that for heating the boil-off gas to an appropriate input temperature of the compressor.

Preferably, a gas supply line connected from the storage tank to the compressor via the heat exchanger; And a gas supply valve provided on the gas supply line to control the flow rate of boil-off gas to be introduced into the compressor via the heat exchanger: After heat exchange with the compressed gas, it may be introduced into the compressor.

Preferably, a bypass valve provided in the heating line to control the flow rate of the boil-off gas to be introduced into the compressor via the heater is further included, and the boil-off gas generated in the storage tank is heated by heat exchange through the heat exchanger Introduced to the compressor, but when the re-liquefaction system is not operated or the load of the re-liquefaction system is low, all or part of the evaporation gas generated in the storage tank bypasses the heat exchanger and heats in the heater through the heating and can be introduced into the compressor.

Preferably, a refrigerant compression unit provided in the refrigerant circulation line and compressing the refrigerant discharged after heat exchange in the heat exchanger; And a refrigerant expansion device provided in the refrigerant circulation line and supplying the refrigerant to the heat exchanger by expanding and cooling the refrigerant. The refrigerant may be expanded and cooled in the expansion device and supplied as a cold heat source to the heat exchanger.

Preferably, in the heat exchanger, the compressed gas compressed in the compressor, the refrigerant expanded and cooled in the refrigerant expansion device, the uncompressed boil-off gas to be introduced from the storage tank to the compressor along the gas supply line, and the refrigerant compression Four streams of refrigerant compressed in the section can be heat exchanged.

Preferably, the refrigerant compression unit may be connected to the refrigerant expansion device and receive expansion energy of the refrigerant from the refrigerant expansion device to compress the refrigerant.

Preferably, the compressor compresses the boil-off gas with the fuel supply pressure of the propulsion engine provided in the ship, but the propulsion engine can receive the compressed boil-off gas at 10 to 20 bara.

Preferably, a pressure reducing device for receiving the compressed gas cooled by heat exchange in the heat exchanger and reducing the pressure; and a gas-liquid separator for gas-liquid separation by receiving the reduced boil-off gas from the pressure reducing device, wherein the flash gas separated in the gas-liquid separator joins the uncompressed boil-off gas stream at the front end of the heat exchanger, and the gas-liquid separator The liquefied gas separated from may be recovered to the storage tank.

According to another aspect of the present invention, a compressor for compressing boil-off gas generated from liquefied gas stored in an onboard storage tank;

a re-liquefaction line connected from the compressor to the storage tank to re-liquefy the boil-off gas and return it to the storage tank;

A heat exchanger provided in the reliquefaction line and cooling the boil-off gas compressed by the compressor;

a separator provided in the re-liquefaction line and supplying liquefied gas to the storage tank by gas-liquid separation of boil-off gas cooled through the heat exchanger;

an off-gas combustion line supplying off-gas separated by the separator to a gas combustion unit (GCU); and

A vapor main for discharging boil-off gas generated in the storage tank from the storage tank;

The GCU is provided with an off-gas treatment system of a re-liquefaction device for a ship, characterized in that for burning the off-gas by receiving the boil-off gas from the vapor main.

Preferably, a heater provided in the off-gas combustion line to heat the off-gas to be supplied to the GCU; an off-gas recirculation line branched from the off-gas combustion line upstream of the heater and connected to the vapor main; and an overpressure prevention valve provided in the off-gas recirculation line.

Preferably, when GCU operation is stopped due to a start or trip of the GCU, the off-gas may be supplied to the vapor main via the off-gas recirculation line through the overpressure prevention valve.

Preferably, a refrigerant circulation unit in which the refrigerant exchanged with the boil-off gas in the heat exchanger circulates; but, the refrigerant of the refrigerant circulation unit may be nitrogen.

Preferably, a first valve provided upstream of the branching point of the off-gas recirculation line in the off-gas combustion line; a pressure compensating line branched off from the reliquefaction line downstream of the compressor and connected to an upper portion of the separator; and a backup line for supplying nitrogen from the buffer tank of the refrigerant circulation unit to the pressure compensation line, wherein boil-off gas or nitrogen is supplied to the separator through the pressure compensation line or gas is discharged through the first valve. Thus, the internal pressure of the separator can be adjusted.

Preferably, it further includes a gas supply line connected from the vapor main to the inboard engine, and transfers the off gas to the vapor main through the off gas recirculation line, together with the boil-off gas discharged from the storage tank. It can be supplied as engine fuel.

Preferably, a liquefied gas supply line connected to the gas supply line from the storage tank; And a vaporizer provided in the liquefied gas supply line and vaporizing the liquefied gas supplied from the storage tank: further comprising, wherein the mixed gas of the off-gas and boil-off gas from the storage tank does not satisfy the calorific value of the engine. In this case, the liquefied gas in the storage tank may be forcibly vaporized and supplied to the mixed gas.

According to another aspect of the present invention, the boil-off gas generated from the onboard storage tank is compressed with a compressor, cooled by heat exchange in a heat exchanger supplied with a refrigerant circulating along the refrigerant circulation line, and re-liquefied,

The boil-off gas generated from the storage tank is heated to an appropriate input temperature of the compressor through a heater, and there is provided a method of re-liquefying boil-off gas of the ship, characterized in that it can be introduced into the compressor.

The boil-off gas generated in the storage tank is heated by heat exchange through the heat exchanger and introduced to the compressor. When the re-liquefaction system is not operated or the load of the re-liquefaction system is low, the boil-off gas generated in the storage tank is transferred to the heat exchanger. Bypassing the machine, it may be heated in the heater through the heating line and introduced into the compressor.

The refrigerant circulating in the refrigerant circulation line is compressed in the refrigerant compression unit, cooled through the heat exchanger, expanded and cooled in the refrigerant expansion device, and supplied as a cold heat source to the heat exchanger, and the refrigerant compression unit is connected to the refrigerant expansion device, The refrigerant may be compressed by receiving expansion energy of the refrigerant from the refrigerant expansion device.

The compressor compresses the boil-off gas with the fuel supply pressure of the propulsion engine provided in the ship, but the propulsion engine can receive the compressed boil-off gas at 10 to 20 bara.

According to another aspect of the present invention, the boil-off gas generated from the liquefied gas in the onboard storage tank is compressed in a compressor,

The boil-off gas compressed in the compressor is cooled in a heat exchanger to be re-liquefied, gas-liquid separated through a separator, and returned to the storage tank,

Off gas separated from the separator is supplied to a Gas Combustion Unit (GCU), and boil-off gas generated in the storage tank and discharged to the vapor main is supplied to the GCU to burn the off gas. There is provided an off-gas treatment method of a re-liquefaction device for a ship.

Preferably, when the operation of the GCU is stopped due to a start or trip of the GCU, offgas separated from the separator may be supplied to the vapor main.

Preferably, the off-gas supplied to the vapor main is mixed with boil-off gas discharged from the storage tank to the vapor main or forced vaporized gas obtained by forcibly vaporizing the liquefied gas in the storage tank to meet the calorific value required by the inboard engine. According to the engine fuel can be supplied.

In the present invention, the cryogenic uncompressed evaporation gas generated from the storage tank is introduced into the compressor through the heat exchanger, used as a cooling heat source of the heat exchanger together with the refrigerant in the refrigerant circulation line, and the cryogenic evaporation gas at the proper input temperature required by the compressor. so that it can be supplied to the compressor. Furthermore, a heating line is provided in which the boil-off gas from the storage tank bypasses the heat exchanger and can be directly supplied to the compressor, and a heater is provided in the heating line so that the re-liquefaction system is not operated or the load of the re-liquefaction system is low. Even at this time, the boil-off gas is heated to an appropriate input temperature so that it can be supplied to the compressor.

In this way, by using the cooling heat of the boil-off gas itself and the cooling heat of the refrigerant cycle to increase the cooling efficiency of the heat exchanger, in order to increase the re-liquefaction rate, additional facilities for compressing the boil-off gas to be re-liquefied to high pressure, such as a boost compressor, are installed and operated. CAPEX and OPEX can be reduced. Regardless of the operation and load of the re-liquefaction system, boil-off gas can be supplied at an appropriate input temperature, preventing damage to the compressor and enabling stable operation.

In addition, since only the residual boil-off gas is re-liquefied after fuel consumption, the load of the refrigerant cycle can be adjusted according to the amount of residual boil-off gas, thereby reducing fuel consumption.

In the present invention, by re-liquefying the boil-off gas generated from the liquefied gas in the storage tank, it is possible to prevent LNG loss and increase the transport efficiency of LNG.

In particular, by discharging off-gas whose nitrogen content has increased due to the continuous operation of the re-liquefaction device and treating it, the re-liquefaction device can be stably operated while maintaining the re-liquefaction performance.

In addition, it is difficult to incinerate or supply as fuel due to its high nitrogen content, and it solves the problem of off-gas, which is not allowed to vent, including methane gas, so that off-gas can be handled flexibly and effectively according to the situation of the ship. let it be

1 schematically shows a boil-off gas re-liquefaction system of a ship according to an embodiment of the present invention.

2 schematically shows an off-gas treatment system of a re-liquefaction device for a ship according to another embodiment of the present invention.

FIG. 3 is a first operational example of the system of the embodiment shown in FIG. 2 .

FIG. 4 is a second operation example of the system of the embodiment shown in FIG. 2 .

FIG. 5 is a third operation example of the system of the embodiment shown in FIG. 2 .

In order to fully understand the operational advantages of the present invention and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are marked with the same numerals as much as possible, even if they are displayed on different drawings.

Hereinafter, in the ship of the present invention, all types of engines that can use liquefied gas and boil-off gas generated from liquefied gas as fuel for engines for propulsion or power generation are installed or use liquefied gas or boil-off gas as fuel for inboard engines. of ships, typically LNG carriers, liquid hydrogen carriers, ships with self-propelled capabilities such as LNG RVs (Regasification Vessel), LNG FPSOs (Floating Production Storage Offloading), LNG FSRUs (Floating Storage Regasification Units) ) may also include offshore structures that do not have propulsion capability but are floating on the sea.

In addition, in the present invention, the liquefied gas can include all types of liquefied gas that can be transported by liquefying the gas at a low temperature, generate boil-off gas in a stored state, and can be used as a fuel for engines and the like. These liquefied gases are, for example, liquefied petrochemicals such as LNG (Liquefied Natural Gas), LEG (Liquefied Ethane Gas), LPG (Liquefied Petroleum Gas), liquefied ethylene gas, and liquefied propylene gas. may be gas. However, in the embodiments to be described later, an example in which LNG, which is one of representative liquefied gases, is applied will be described.

1 schematically shows a boil-off gas re-liquefaction system of a ship according to an embodiment of the present invention.

Compressors (100a, 100b) for re-liquefying the boil-off gas generated in the storage tank in which the liquefied gas is stored provided on the ship as shown in FIG. 1, receiving and compressing the boil-off gas generated in the storage tank (T), It includes a heat exchanger 200 that receives all or part of the boil-off gas compressed by the compressor and cools it by heat exchange with the uncompressed boil-off gas and the refrigerant to be introduced into the compressor. To this end, a gas supply line (GL) is connected from the storage tank (T) to the compressors (100a, 100b) via a heat exchanger, and a re-liquefaction line (RL) for re-liquefying the boil-off gas at the rear end of the compressor and supplying it to the storage tank is each is provided.

In addition, a refrigerant circulation line (CL) in which the refrigerant supplied to the heat exchanger 200 circulates is provided, and the refrigerant circulation line is provided with a refrigerant expansion device 650 in which the refrigerant supplied to the heat exchanger is expanded and cooled, and after heat exchange in the heat exchanger. A refrigerant compression unit 600 for compressing the discharged refrigerant is provided.

The refrigerant compression unit 600 is provided as a compander compressor and is axially connected to the refrigerant expansion device 650 to receive expansion energy of the refrigerant and drive the compander compressor. The refrigerant compression unit may be driven by a motor, and the motor may be connected to the refrigerant expansion device 650 to receive expansion energy of the refrigerant and compress the refrigerant while the motor is driven.

The refrigerant compressed in the refrigerant compression unit 600 is introduced into the heat exchanger 200, cooled, supplied to the refrigerant expansion device 650 along the refrigerant circulation line CL, expanded and cooled, and returned to the heat exchanger 200. supplied as a refrigerant.

Accordingly, in the heat exchanger 200 in this embodiment, all or part of the compressed boil-off gas, the uncompressed boil-off gas to be introduced into the compressor, the refrigerant expanded and cooled in the refrigerant expansion device, and the refrigerant compressed in the refrigerant compression unit are 4 The branch streams exchange heat.

As the refrigerant supplied to the heat exchanger while circulating in the refrigerant circulation line CL, for example, nitrogen (N ₂ ) may be used. In the case of supplying compressed refrigerant to a heat exchanger, cooling it with the cooling heat of the refrigerant itself, expanding it, supplying it to the heat exchanger, and cooling it by exchanging heat with the boil-off gas, the main component is methane to cool the boil-off gas to the liquefaction temperature. Due to the difference in heat capacity between boil-off gas and nitrogen, a large amount of nitrogen refrigerant is required, resulting in the use of most of the cooling heat of the refrigerant cycle for cooling the nitrogen refrigerant itself, and increased capacity of devices that compress and expand the refrigerant, There is a problem of causing an increase in power consumption. In order to solve this problem, in the present embodiment, the cryogenic uncompressed boil-off gas generated from the storage tank is configured to be introduced to the compressor through the heat exchanger, thereby reducing the refrigerant flow rate required in the refrigerant cycle, and accordingly, a device for compressing and expanding the refrigerant. Reduces capacity and power consumption, reducing installation and operating costs.

In the system of this embodiment, looking at the process of treating the boil-off gas generated from the liquefied gas in the storage tank, the boil-off gas generated in the storage tank T is introduced into the compressors 100a and 100b via the heat exchanger 200 .

In the compressor (100a, 100b) to compress the boil-off gas, for example, the boil-off gas can be compressed by the fuel supply pressure of the main engine or propulsion engine of the ship. For example, if a DF engine is provided, it can be compressed to 5.5 barg, to 15 barg if an X-DF engine is provided, and to 300 barg if an ME-GI engine is provided. The compressed boil-off gas may be supplied as fuel to the propulsion engine E1 and the power generation engine E2 of the ship, and the remaining boil-off gas after fuel supply may be re-liquefied.

According to ship regulations, a compressor that supplies fuel with an engine must be designed for redundancy in case of an emergency. This means that it is designed to be usable. To this end, the compressor is composed of a main compressor (100a) and a redundancy compressor (100b), and in normal operation, the main compressor, that is, one compressor is operated to supply fuel to the propulsion engine and power generation engine, and the remaining amount of compressed gas is It can be re-liquefied through the re-liquefaction line (RL).

The boil-off gas compressed by the compressor is introduced into the heat exchanger 200 along the reliquefaction line RL and cooled. The boil-off gas to be compressed and re-liquefied and the refrigerant compressed in the refrigerant compression unit form the hot stream of the heat exchanger, and the uncompressed boil-off gas and the refrigerant cooled by expansion in the refrigerant expansion device form the cold stream.

In the heat exchanger 200, four streams are heat-exchanged, and the hot stream is cooled by heat exchange with the cold stream. The heat exchanger may be provided with, for example, a brazed aluminum heat exchanger (BAHE).

The introduction and discharge positions of each stream in the heat exchanger may be different so that the heat exchange between the hot stream and the cold stream is more effective and the compressed gas to be re-liquefied is cooled.

The nitrogen refrigerant introduced into the heat exchanger after expansion cooling in the cold stream of the heat exchanger has a temperature of around -167 ℃, for example, if the pressure is around 10 bar, and is higher than the uncompressed evaporation gas around -50 ℃, which is another cold stream of the heat exchanger. The temperature is low. Therefore, when introduced together in the heat exchanger, all of the cold heat of the nitrogen refrigerant is not used for cooling the compressed gas to be re-liquefied, and some of the cold heat can be absorbed by other flows. It is introduced downstream so that it passes through all of the heat exchanger, and the uncompressed boil-off gas flow (GL) having a high temperature in the cold stream is introduced into the middle part of the heat exchanger.

Therefore, the compressed gas of the re-liquefaction line passes through the high-temperature region of the heat exchanger and the low-temperature region and is sequentially cooled. is supplied and cooled, and in the low-temperature region, it is sequentially cooled by exchanging heat with one cold stream and the refrigerant of the refrigerant circulation line immediately after being introduced into the heat exchanger.

By exchanging heat in this way, the compressed gas to be re-liquefied can be cooled more effectively to increase the re-liquefaction rate, and damage to the device can be prevented by preventing thermal fatigue of the heat exchanger.

On the other hand, the boil-off gas cooled by heat exchange in the heat exchanger is introduced into the decompression device 400 of the reliquefaction line and reduced in pressure, and the boil-off gas reduced in the decompression device is introduced into the gas-liquid separator 500.

The decompression device 400 may be composed of an expander that depressurizes the compressed and cooled boil-off gas or an expansion valve such as a Joule-Thomson valve. Through decompression, the evaporation gas is cooled by adiabatic expansion or isentropic expansion.

The evaporation gas depressurized and additionally cooled in the pressure reducing device is introduced into the gas-liquid separator 500, and the liquid separated in the gas-liquid separator is supplied to the storage tank T along the reliquefaction line RL and stored again. However, since flash gas (a gas) and liquefied gas (a liquid) may not be phase-separated 100% even though the gas-liquid separator passes through the gas-liquid separator in the present embodiments, the separated liquid or liquefied gas may include unseparated flash gas.

The flash gas separated in the gas-liquid separator is supplied from the top of the gas-liquid separator to the uncompressed boil-off gas flow in front of the heat exchanger and heater through the flash gas line FL, and may be introduced into the compressor via the heat exchanger or heater.

The system of this embodiment increases the cooling efficiency of the heat exchanger by using the cooling heat of the boil-off gas itself and the cooling heat of the refrigerant cycle, so as to increase the re-liquefaction rate. CAPEX and OPEX can be saved because it can be installed and operated.

On the other hand, boil-off gas generated in the storage tank (T) is discharged from the storage tank at a cryogenic temperature in the range of -140 ° C to -100 ° C depending on the tank operation, the type of compressor provided for engine fuel supply Depending on the method, the evaporation gas introduced may be required to be within a certain temperature range. In particular, a compressor for fuel supply of a medium-pressure engine such as an X-DF engine may be installed as a room temperature compressor. The low-temperature evaporation gas generated in the tank passes through the heat exchanger and can be sufficiently heated and introduced to the compressor. Even if it passes through the steamer, the evaporation gas is not sufficiently heated to the proper input temperature required by the compressor.

In order to solve this problem, in the system of this embodiment, a heating line (BL) that can be directly introduced into the compressors 100a and 100b bypassing the heat exchanger 200 in the storage tank T is provided, and the evaporation A heater 300 capable of heating gas was provided.

A gas supply valve (GV) is provided in the gas supply line (GL) to control the flow rate of boil-off gas to be introduced into the compressors (100a, 100b) via the heat exchanger (200), and the heater (300) is provided in the heating line (BL) A bypass valve (BV) for controlling the flow rate of boil-off gas to be introduced into the compressors 100a and 100b via is provided.

When the re-liquefaction system is operated, the boil-off gas generated in the storage tank (T) is heated by heat exchange through the heat exchanger 200 and introduced into the compressors 100a and 100b, but the re-liquefaction system is not operated or the re-liquefaction system is loaded When the load is low, all or part of the boil-off gas generated in the storage tank bypasses the heat exchanger and is heated in the heater 300 through the heating line BL to be introduced into the compressors 100a and 100b.

By controlling the opening and closing of the gas supply valve (GV) and the bypass valve (BV), the flow rate of boil-off gas introduced to the compressor through the heat exchanger and the heater is adjusted, so that the re-liquefaction system is not operating or the re-liquefaction system is Even when the load is low, the compressor can supply boil-off gas at the proper input temperature required. In this way, boil-off gas can be supplied at an appropriate input temperature regardless of the operation and load of the re-liquefaction system, preventing damage to the compressor and stably operating it.

2 schematically shows an off-gas treatment system of a re-liquefaction device for a ship according to another embodiment of the present invention, and FIGS. 3 to 5 show various operation examples of the system of this embodiment, respectively.

As shown in FIG. 2, the off-gas treatment system of the re-liquefaction device of the present embodiment is a re-liquefaction device for re-liquefying boil-off gas generated from a storage tank (CT) in which liquefied gas is stored on board and returning it to the storage tank. A system for off-gas treatment, a compressor 150 that receives and compresses boil-off gas, and a re-liquefaction line (RL) that is connected from the compressor 150 to the storage tank and re-liquefies the boil-off gas and returns it to the storage tank (CT). includes

Evaporation gas generated from the storage tank CT is discharged to the vapor main VM, and may be supplied to the engine fuel from the vapor main along the gas supply line GL.

An FG compressor 100 for compressing boil-off gas according to the fuel supply pressure of the inboard engine is provided in the gas supply line GL.

In the FG compressor 100, for example, 5.5 barg when a DF engine is provided, 15 barg when an X-DF engine is provided, and 300 barg when an ME-GI engine is provided. Can compress the increased pressure. The compressed boil-off gas may be supplied as fuel for the engine E, and the boil-off gas not supplied as fuel may be re-liquefied along a re-liquefaction line.

The compressor 150 of the re-liquefaction line may additionally compress the boil-off gas compressed by the FG compressor in order to increase the re-liquefaction rate of the boil-off gas, and further compress the boil-off gas compressed by the FG compressor 100 for re-liquefaction. It may not be installed if there is no need to do so.

The boil-off gas compressed in the compressor 150 is introduced into the heat exchanger 200 along the reliquefaction line RL and cooled through heat exchange with the refrigerant.

In the reliquefaction line RL, a heat exchanger 200 for cooling the boil-off gas compressed by the compressor and a separator 300 for gas-liquid separation of the boil-off gas cooled in the heat exchanger and supplying the liquefied gas to the storage tank are provided. If necessary, the evaporation gas cooled in the heat exchanger may be introduced into the separator after depressurization through a decompression device (not shown).

In the heat exchanger 200, the refrigerant circulating in the refrigerant circulation unit (not shown) and the uncompressed evaporation gas generated in the storage tank may be cooled by heat exchange with a cooling heat source.

The refrigerant circulation unit includes a refrigerant circulation line in which a refrigerant circulates, and nitrogen (N ₂ ) may be used as a refrigerant circulating in the refrigerant circulation line. Nitrogen can be used as a refrigerant of the heat exchanger after going through compression, cooling and expansion cooling processes along the refrigerant circulation line, and can circulate through the refrigerant circulation line while returning to the compression step again.

The evaporation gas cooled in the heat exchanger is introduced to the separator 300 along the reliquefaction line RL, and the reliquefaction gas separated from the separator is transferred to the storage tank CT by opening and closing of the liquid level control valve downstream of the separator. .

When the liquid level control valve at the rear of the separator is opened to transfer the liquefied gas from the separator 300 to the storage tank, the internal pressure of the separator may change. The internal pressure of the separator can be maintained by

At this time, if the liquefied gas cooled by heat exchange with the nitrogen refrigerant in the refrigerant circulation part is supercooled and flows into the separator, off-gas is not generated or less generated, and when the liquid level control valve at the rear of the separator is opened, the internal pressure of the separator may drop rapidly. . In this embodiment, a pressure compensating line (PL) branched from the reliquefaction line (RL) downstream of the compressor 150 and connected to the top of the separator 300 so that the internal pressure can be maintained by compensating for the pressure of the separator at this time. and a backup line BL for supplying nitrogen to the pressure compensation line. Through this, when the liquefied gas is transferred from the separator to the storage tank, the internal pressure of the separator can be maintained by supplying boil-off gas or nitrogen to the separator through the pressure compensation line (PL).

A pressure sensor (PI) for detecting the pressure inside the separator and a liquid level sensor (LI) for detecting the liquid level inside the separator are provided, and a liquid level controller ( LIC) is provided. A pressure compensation valve (PV) is provided downstream of the joining point of the backup line (BL) in the pressure compensation line (PL), and a first shutoff valve (SV1) is provided upstream of the joining point of the backup line, respectively. A second shutoff valve (SV2) is provided.

According to the pressure inside the separator detected by the pressure sensor (PI), the pressure controller (PIC) adjusts the pressure of the boil-off gas or nitrogen in the pressure compensation valve (PV) to the upper part of the separator 300 through the pressure compensation line (PL). supply

Nitrogen to be supplied to the separator through the backup line (BL) may be supplied from the N ₂ Buffer Tank of the Shipside N ₂ Supply System or the N ₂ Inventory System that supplies and replenishes the nitrogen refrigerant circulating in the refrigerant circulation unit.

However, if the re-liquefaction device is continuously operated, even if it passes through the re-liquefaction device, nitrogen with a lower liquefaction point than methane is not liquefied and vaporized first when the temperature changes, and some nitrogen is supplied for separator pressure control, etc. The nitrogen content in the evaporation gas discharged from the evaporation gas gradually increases, which may lead to deterioration of the performance of the liquid solution. In addition, even if the off-gas having a high nitrogen content is separated from the separator, it is difficult to supply it as fuel because the high nitrogen content does not satisfy the calorific value of the engine, and since it contains methane, it is not allowed to vent it directly into the atmosphere.

In order to solve this problem, the system of the present embodiment provides an off-gas combustion line (OSL) for supplying the off-gas separated from the separator 300 to a gas combustion unit (GCU) so that the off-gas can be effectively treated. did

Through this, the GCU receives the boil-off gas from the vapor main (VM) and burns it together with the off-gas.

In addition, the off-gas combustion line (OSL) is provided with a heater 400 for heating off-gas to be supplied to the GCU, and an off-gas recirculation line (FL) branched from the off-gas combustion line upstream of the heater and connected to the vapor main. ) is provided, and an overpressure prevention valve (OV3) is provided in the off-gas recirculation line.

A first valve OV1 is provided upstream of the branching point of the off-gas recirculation line in the off-gas combustion line OSL, and can be controlled to discharge off-gas from the separator to the off-gas combustion line or the off-gas recirculation line.

A liquefied gas supply line (LL) connected from the storage tank (CT) to the gas supply line (GL) is provided, and a vaporizer (500) for vaporizing liquefied gas supplied from the storage tank is provided on the liquefied gas supply line.

Looking at the off-gas treatment operation example of the present embodiment system through FIGS. 3 to 5, first, as in the first operation example shown in FIG. It is supplied to the GCU through the heater 400 along the (OSL), and according to the amount of the off-gas discharged to the GCU, the boil-off gas (NBOG) that can burn it is supplied to the GCU through the vapor main (VM) to supply the off-gas be treated by incineration.

During GCU startup or when GCU operation is stopped due to a trip, open the overpressure prevention valve (OV3) to supply off-gas to the vapor main (VM) through the off-gas recirculation line (FL) You can operate the reliquefaction device while doing so.

As another operational example, in the second operational example of FIG. 4 , offgas separated from the separator may be supplied as fuel to the engine (E) and treated. In this case, as described above, the calorific value of the engine may not be satisfied due to the high nitrogen content of the off-gas. ), and the boil-off gas (NBOG) discharged from the storage tank (CT) to the vapor main (VM) is mixed with the off-gas and supplied to the engine (E) through the FG compressor 100 according to the calorific value of the engine. It was configured.

On the other hand, since the amount of off-gas is larger than the amount of boil-off gas generated in the storage tank, the engine's calorific value may not be satisfied with only naturally-generated boil-off gas. In the third operation example shown in FIG. 5, in this case, the liquefied gas in the storage tank CT is supplied to the vaporizer 500 along the liquefied gas supply line LL for forced vaporization, and the forced vaporized gas is supplied to the gas supply line GL. ), mixed with off-gas or a mixture of NBOG and off-gas, supplied to the FG compressor 100, compressed, and then supplied as engine (E) fuel.

As described above, in this embodiment, the transport efficiency can be increased by re-liquefying the boil-off gas generated in the storage tank, and the re-liquefaction device is effectively treated by discharging the off-gas having a high nitrogen content due to the continuous operation of the re-liquefaction device. It enables stable operation while maintaining the liquid performance of the

The present invention is not limited to the above embodiments, and it can be practiced with various modifications or variations within a range that does not deviate from the technical gist of the present invention to those skilled in the art to which the present invention belongs. It is self-evident.

Claims (22)

1. A compressor for compressing boil-off gas generated from liquefied gas stored in a storage tank provided on the ship;

   a heat exchanger cooling the compressed gas compressed by the compressor;

   a refrigerant circulation line through which the refrigerant supplied to the heat exchanger circulates;

   Ga line connected from the storage tank to the compressor; and

   Including: a heater provided in the ga-line,

   The heater boil-off gas re-liquefaction system of the ship, characterized in that for heating the boil-off gas to an appropriate input temperature of the compressor.
2. According to claim 1,

   a gas supply line connected from the storage tank to the compressor via the heat exchanger; and

   Further comprising: a gas supply valve provided in the gas supply line to control the flow rate of boil-off gas to be introduced into the compressor via the heat exchanger;

   Boiled gas generated in the storage tank is introduced into the compressor after heat exchange with the compressed gas in the heat exchanger through the gas supply line.
3. According to claim 2,

   Further comprising: a bypass valve provided in the ga-line to control the flow rate of boil-off gas to be introduced into the compressor via the heater;

   The evaporated gas generated in the storage tank is heated by heat exchange through the heat exchanger and introduced into the compressor,

   When the re-liquefaction system is not operated or the load of the re-liquefaction system is low, all or part of the boil-off gas generated in the storage tank bypasses the heat exchanger and is heated in the heater through the gauging line and introduced into the compressor Boiled gas re-liquefaction system of a ship, characterized in that.
4. According to claim 3,

   a refrigerant compression unit provided in the refrigerant circulation line and compressing the refrigerant discharged after heat exchange in the heat exchanger; and

   Further comprising a refrigerant expansion device provided in the refrigerant circulation line and supplying the refrigerant to the heat exchanger by expanding and cooling the refrigerant,

   The refrigerant in the refrigerant circulation line is compressed in the refrigerant compression unit, cooled through the heat exchanger, expanded and cooled in the refrigerant expansion device, and supplied as a cold heat source to the heat exchanger.
5. According to claim 4,

   In the heat exchanger, compressed gas compressed in the compressor, refrigerant expanded and cooled in the refrigerant expansion device, uncompressed evaporation gas to be introduced from the storage tank to the compressor along the gas supply line, and compressed in the refrigerant compression unit A system for reliquefying boil-off gas of a ship, characterized in that four flows of refrigerant are heat-exchanged.
6. According to claim 4,

   The refrigerant compression unit is connected to the refrigerant expansion device and receives the expansion energy of the refrigerant from the refrigerant expansion device to compress the refrigerant.
7. According to claim 6,

   The compressor compresses the boil-off gas with the fuel supply pressure of the propulsion engine provided on the ship,

   The ship's boil-off gas re-liquefaction system, characterized in that the propulsion engine is supplied with boil-off gas compressed to 10 to 20 bara.
8. According to any one of claims 1 to 7,

   a decompression device for receiving the compressed gas cooled by heat exchange in the heat exchanger and reducing the pressure; and

   Further comprising: a gas-liquid separator for gas-liquid separation by receiving the reduced boil-off gas from the pressure reducing device,

   The flash gas separated in the gas-liquid separator joins the uncompressed boil-off gas flow in front of the heat exchanger, and the liquefied gas separated in the gas-liquid separator is recovered to the storage tank. .
9. A compressor for compressing boil-off gas generated from liquefied gas stored in an onboard storage tank;

   a re-liquefaction line connected from the compressor to the storage tank to re-liquefy the boil-off gas and return it to the storage tank;

   A heat exchanger provided in the reliquefaction line and cooling the boil-off gas compressed by the compressor;

   a separator provided in the re-liquefaction line and supplying liquefied gas to the storage tank by gas-liquid separation of boil-off gas cooled through the heat exchanger;

   an off-gas combustion line supplying off-gas separated by the separator to a gas combustion unit (GCU); and

   A vapor main for discharging boil-off gas generated in the storage tank from the storage tank;

   In the GCU, the off-gas treatment system of the marine re-liquefaction device, characterized in that for receiving the boil-off gas from the vapor main and burning the off-gas.
10. According to claim 9,

    a heater provided in the off-gas combustion line to heat the off-gas to be supplied to the GCU;

    an off-gas recirculation line branched from the off-gas combustion line upstream of the heater and connected to the vapor main; and

    An overpressure prevention valve provided in the off-gas recirculation line: The off-gas treatment system of the marine re-liquefaction device further comprising
11. According to claim 10,

    When the operation of the GCU is stopped due to the start or trip of the GCU, the off-gas is supplied to the vapor main through the off-gas recirculation line through the overpressure prevention valve. Off-gas treatment system of liquefier.
12. According to claim 10,

    A refrigerant circulation unit in which the refrigerant that is heat-exchanged with the boil-off gas in the heat exchanger circulates;

    The refrigerant of the refrigerant circulation unit is an off-gas treatment system of a marine re-liquefaction device, characterized in that nitrogen.
13. According to claim 12,

    A first valve provided upstream of a branch point of the off-gas recirculation line in the off-gas combustion line;

    a pressure compensating line branched off from the reliquefaction line downstream of the compressor and connected to an upper portion of the separator; and

    A backup line for supplying nitrogen from the buffer tank of the refrigerant circulation unit to the pressure compensation line;

    The off-gas treatment system of the marine re-liquefaction device, characterized in that the internal pressure of the separator can be adjusted by supplying boil-off gas or nitrogen to the separator through the pressure compensation line or discharging gas through the first valve.
14. According to claim 10,

    Further comprising: a gas supply line connected from the vapor main to the inboard engine;

    The off-gas treatment system of the marine re-liquefaction device, characterized in that the off-gas is transferred to the vapor main through the off-gas recirculation line and supplied as fuel of the engine together with the boil-off gas discharged from the storage tank.
15. According to claim 14,

    a liquefied gas supply line connected to the gas supply line from the storage tank; and

    Further comprising a vaporizer provided in the liquefied gas supply line and vaporizing the liquefied gas supplied from the storage tank;

    When the mixed gas of the off-gas and boil-off gas from the storage tank does not satisfy the calorific value of the engine, the liquefied gas in the storage tank is forcibly vaporized and supplied to the mixed gas. Off-gas treatment system.
16. The boil-off gas generated from the onboard storage tank is compressed with a compressor, cooled by heat exchange in the heat exchanger supplied with the refrigerant circulating along the refrigerant circulation line, and re-liquefied,

    Boiled gas generated from the storage tank is heated to an appropriate input temperature of the compressor through a heater and can be introduced into the compressor.
17. According to claim 16,

    The evaporated gas generated in the storage tank is heated by heat exchange through the heat exchanger and introduced into the compressor,

    When the re-liquefaction system is not operated or the load of the re-liquefaction system is low, the boil-off gas generated in the storage tank bypasses the heat exchanger and is heated by the heater through the heating line and introduced into the compressor. A method for re-liquefying evaporation gas of ships.
18. According to claim 17,

    The refrigerant circulating in the refrigerant circulation line is compressed in the refrigerant compression unit, cooled through the heat exchanger, expanded and cooled in the refrigerant expansion device, and supplied to the heat exchanger as a cold heat source,

    The refrigerant compression unit is connected to the refrigerant expansion device, the ship's boil-off gas re-liquefying method, characterized in that for compressing the refrigerant by receiving the expansion energy of the refrigerant from the refrigerant expansion device.
19. According to claim 18,

    The compressor compresses the boil-off gas with the fuel supply pressure of the propulsion engine provided on the ship,

    The propulsion engine is a method of re-liquefying boil-off gas of a ship, characterized in that supplied with boil-off gas compressed to 10 to 20 bara.
20. The boil-off gas generated from the liquefied gas in the onboard storage tank is compressed in the compressor,

    The boil-off gas compressed in the compressor is cooled in a heat exchanger to be re-liquefied, gas-liquid separated through a separator, and returned to the storage tank,

    Off gas separated from the separator is supplied to a Gas Combustion Unit (GCU), and boil-off gas generated in the storage tank and discharged to the vapor main is supplied to the GCU to burn the off gas. Off-gas treatment method of re-liquefaction equipment for ships.
21. 21. The method of claim 20,

    When the operation of the GCU is stopped due to the start or trip of the GCU, the off-gas separated from the separator is supplied to the vapor main.
22. According to claim 21,

    The off-gas supplied to the vapor main is mixed with the boil-off gas discharged from the storage tank to the vapor main or the forced vaporized gas obtained by forcibly vaporizing the liquefied gas in the storage tank to match the calorific value required by the engine fuel Off-gas treatment method of the re-liquefaction device for ships, characterized in that supplied to.

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